Critical percolation clusters in seven dimensions and on a complete graph

Abstract

We study critical bond percolation on a seven-dimensional (7D) hypercubic lattice with periodic boundary conditions and on the complete graph (CG) of finite volume V. We numerically confirm that for both cases, the critical number density n(s,V) of clusters of size s obeys a scaling form n(s,V) s-τ n (s/Vd* f) with identical volume fractal dimension d* f=2/3 and exponent τ = 1+1/d* f=5/2. We then classify occupied bonds into bridge bonds, which includes branch and junction bonds, and non-bridge bonds; a bridge bond is a branch bond if and only if its deletion produces at least one tree. Deleting branch bonds from percolation configurations produces leaf-free configurations, whereas, deleting all bridge bonds leads to bridge-free configurations. It is shown that the fraction of non-bridge (bi-connected) bonds vanishes n, CG→0 for large CGs, but converges to a finite value n, 7D =0.006 \, 193 \, 1(7) for the 7D hypercube. Further, we observe that while the bridge-free dimension d* bf=1/3 holds for both the CG and 7D cases, the volume fractal dimensions of the leaf-free clusters are different: d* f, 7D = 0.669 (9) ≈ 2/3 and d* f, CG = 0. 333 7 (17) ≈ 1/3. We also study the behavior of the number and the size distribution of leaf-free and bridge-free clusters. For the number of clusters, we numerically find the number of leaf-free and bridge-free clusters on the CG scale as V, while for 7D they scale as V. Our work demonstrates that the geometric structure of high-dimensional percolation clusters cannot be fully accounted for by their complete-graph counterparts.